Numerical simulation of land subsidence induced by groundwater overexploitation in Su-Xi-Chang area, China

Abstract

Su-Xi-Chang area is one of the typical regions in China which suffers from severe land subsidence. Various field monitoring records were integrated to study the characteristics and mechanisms of land subsidence in this region. The development of the land subsidence in this region shows a tight spatial and temporal correlation with the groundwater pumping. Based on the analysis of the field data, it is found that the deformation patterns of the hydrogeologic units are greatly related to the hydrogeologic properties and groundwater level variations. Some have an elastic behavior, others may have an elastic–plastic rheology. Hence, a 3D finite element numerical model considering the rheological properties of the soil was developed to simulate the groundwater level and land subsidence. Both hydraulic conductivity and specific storage were expected to vary with the porosity during the process of consolidation. Multiscale finite element method (MsFEM) was applied to solve the model during the period from 1996 to 2004. After calibrating the model with the observed groundwater level and subsidence data, the parameters of the multi-layers system were estimated. The calibrated model outputs fit reasonably well with the observed data. Consequently the model can be applied to predict groundwater level and land subsidence in future pumping scenarios. The model predictive results show that land subsidence rate can be controlled and even rebound may occur after the implementation of the groundwater exploitation prohibition.